HU217737B - Flow meter having a fluid oscillator - Google Patents

Abstract

The present invention provides a fluid oscillator flowmeter with a two-dimensional fluid jet oscillating on either side of the longitudinal plane of symmetry of the flowmeter and comprising a single oscillator chamber (14), a barrier (22) disposed in the oscillator chamber (14). , a cavity (24) placed in the flow path and scanned by the jet along the oscillation line of the jet, further comprising elements for determining the flow rate by measuring the pressure difference and elements for determining the flow rate from the pressure difference. The present invention comprises a pressure outlet (P3) located in the intersection of the symmetry plane (P) of the flow meter and the bottom of the cavity (24) and a pressure outlet (P3 and a pressure outlet P2) located on both sides of the symmetry plane (P) pressure differential measuring element

Description

BACKGROUND OF THE INVENTION The present invention relates to a fluid oscillator flowmeter which allows the measurement of fluid or gas fluid flow.

U.S. Pat. No. 4,244,230 discloses a fluid oscillator flowmeter which is symmetrically arranged in a particular plane of symmetry. The inlet of the flow meter is configured as a nozzle or gauge that transmits a two-dimensional fluid jet to a chamber. Inside the chamber is formed a barrier having a front cavity in the fluid jet path. Oscillation of the fluid is perpendicular to the plane of symmetry of the flowmeter and together with the jet, two vortexes are formed on one side of the jet. Each vortex is alternately amplified and weakened in a different phase from the other. During oscillation, the impact point of the beam scans the entire wall of the cavity.

On the respective sides of the symmetry plane, there are two pressure outlet points connected to one or more pressure sensors so that they can measure the oscillation of the beam in the cavity. 1 is a time function of the electrical output signal S corresponding to the pressure difference between the two pressure outlet points. It is also shown in Fig. 1 that the output time function S has two vertices at each of its two extreme values, each of which has recesses. The deepest point of the recess between the two peaks corresponds to the point of impact of the beam, which is subject to the maximum fluctuation of the beam.

If you already create a beam that scans the aforementioned cavity away from the plane of symmetry after passing through the pressure exit points, the beam continues its path to its maximum deflection.

When the beam has reached its maximum deflection, the pressure measured at the pressure outlet point will decrease. Thus, once the beam has reached its maximum deflection point, that is, the minimum of the recess between the two peaks, the beam returns to the symmetry plane while approaching the second pressure outlet point. The second peak corresponds to the passage of the beam at the second pressure outlet and then to the opposite pressure outlet.

By selecting an appropriate output signal S, the otherwise analogue waveform can be converted to a digital rectangular signal. Each rectangle will be proportional to the amount of fluid passing through the flowmeter. The flow can thus be determined by counting the rectangular waves.

The accuracy of the measurement corresponds to a half oscillation period.

Thus, if the flow is interrupted when the oscillation is interrupted, the exact location of the point of impact of the beam at the bottom of the cavity will be unknown and the measurement will be uncertain.

It is an object of the present invention to provide a flowmeter that further improves the flowmeter above so that its accuracy is at least twice as accurate, but without increasing the frequency of oscillation in the cavity.

It has been discovered that at least one pressure outlet point is formed as a measuring point in addition to the pressure outlet points located symmetrically on the two sides of the symmetry axis in the intersection line of the symmetry plane and the deepest part of the cavity. The differential pressure is then measured:

(a) between pressure release points on either side of the symmetry plane; and

b) measuring the pressure at the pressure outlet point located in the plane of symmetry.

The square marks produced by the differential pressure are at least twice the size of the solution quoted in the introduction, and each rectangular wave corresponds to a smaller flow volume unit. This increases the accuracy of the measurement.

The pressure outlet measurement points are located symmetrically with respect to the plane of symmetry at locations within the cavity at the maximum radius of deflection, i.e. near the maximum of the measuring limit.

The invention thus provides a two-dimensional fluid oscillator flowmeter transverse to the longitudinal plane of symmetry of the flowmeter with a fluid jet oscillating on both sides thereof, and comprising an oscillator chamber, a barrier in the oscillator chamber, and a jet cavities scanned by the beam, and elements determining its flow rate by measuring the pressure difference, and signal processing elements determining the flow rate from the pressure difference.

The flow meter consists of a pressure outlet located at the intersection line of the flow meter symmetry plane and the bottom of the cavity and a pressure differential element measuring between the pressure outlet and the pressure outlet locations symmetrically located on both sides of the symmetry plane.

The pressure outlet locations are preferably located at points corresponding to the maximum deflections of the beam within the cavity.

Advantageously, a pressure loss element is optionally located at a pressure outlet at the intersection plane of the symmetry plane and the bottom of the cavity.

The invention will now be described in more detail by way of exemplary embodiments in the accompanying drawings. The

Figure 1 shows the waveform of a known flow meter as a function of time, a

Figure 2 is a plan view of the flow meter of the present invention and the associated signal processing unit, schematically,

Figure 3 shows a barrier used in the flowmeter of the present invention;

Figure 4 also shows the waveforms of the flowmeter of the present invention as a function of time, as a function of time as a result of the differential pressure, as well as the computable quadratic waves.

HU 217 737 Β

Thus, Figure 2 illustrates an exemplary embodiment of the flow meter of the present invention which is applicable to both liquids and gases. The flowmeter includes a fluid inlet 10, one end of which is connected to an inlet tube 12 for transporting fluid fluid and the other end to an oscillator chamber 14.

The fluid inlet 10 comprises a settling chamber 16 having a parallelogram cross-section through which the fluid flowing in the circular cross-section conduit is converted to a rectangular or square beam. One end of a convergent element 18 is connected to the settling chamber 16, the other end of which is connected to the inlet 20 of the oscillator chamber 14. The inlet port 20 is configured in a known manner to ensure that in the oscillator chamber 14 a two-dimensional oscillating beam is formed perpendicular to the symmetry plane P of the flowmeter.

An oscillator chamber 14 is provided with a barrier 22 having a cavity 24 formed on the side facing the inlet port 20. The fluid jet entering the oscillator chamber 14 scans the inner wall of the cavity during oscillation.

The fluid exits the oscillator chamber through channels 26 and 28 formed between the oscillator chamber 14 and the barrier wall 22. Channels 26 and 28 are joined to an outlet 30 and connected to an outlet 32.

Flow measurement is the number of times the beam scans the bottom of cavity 24 during oscillation. The oscillation frequency will be proportional to the flow rate.

Figure 2 shows that pressure is measured with a pressure sensor located at _three pressure outlet locations P _b P ₂ and P ₃ . P ,, P _2, P ₃ pressure tappings all places in Figure 2 as well as in Figure 3, where the barrier 22 is a perspective view seen clearly observed. These pressure release points P _b P ₂ , P _{3 are} formed by a channel, one end of which extends into the cavity 24 and the other end is led, for example, on the upper face of the dam 22.

The inlet of the pressure outlet locations Ρ and P _{2 is, in} the exemplary embodiment, symmetrically formed on both sides of the symmetry plane P at half of the height of the barrier 22. It is expedient to arrange the inlet points P and P ₂ where the radius is maximally deflected.

It is known that the position of maximum jet deflection is very close to the flow rate of the fluid. In this way, the locations of the pressure outlet locations P ₁ and P ₂ are exactly the same as the maximum displacement for the given flow rate.

As shown in Figure 1, the difference between the position of the deflection point and the position of the pressure outlet increases the depth of the recess between the two peaks when the beam passes over the P and P ₂ pressure outlets and when the beam deflects due to oscillation. from the P symmetry plane. In the case where the amplitude is not large enough for the beam to pass through the pressure exit points P ₍ and P ₂₎ as the beam moves away from the plane of symmetry, this phenomenon is not observed. The pressure outlet locations P | and P ₂ are arranged so that the measurement During this procedure, the recess between the two peaks, which is created when the beam passes over the pressure exit points P _b and P ₂ , shall be neither wide nor deep enough to interfere with the measurement.

Referring now to Fig. 2, it is seen that the pressure outlet locations P ₁ and P ₂ are connected to a T-shaped tube 36.

For example, _three pressure tappings AP location of the dam 22 and is positioned in the cavity 24 of the bottom half of the line of intersection P of symmetry. The output pipe 38 connected to the T-shaped outlet pipe 36 and the stationary pressure tappings connecting P ₃ is connected to a pressure sensor 40, which may be for example silicon, or active, or any other known heat sealing a pressure sensor, which is used flowmeter. A Validyne DPI 103 type sensor manufactured by Validyne Engineering Corporation can be used as a pressure sensor.

In a further exemplary embodiment, each of the pressure outlet locations P _b P ₂ and P ₃ is connected to a separate pressure sensor and produces the desired signal by properly processing their signals.

The output signal S of the pressure sensor 40 is at the pressure outlet P ₃ , which is the base and reference location, and at the outlet of the pipe 36, the P! and P ₂ measures the difference in pressure between the pressure outlet locations. Fig. 4 shows the change in the output signal S over time. The simplicity and clarity sake, the cavities that may emerge in the signals at the tip and to correspond to the beam during oscillation of the symmetric P _t and P ₂ pressure tappings sites passes through, is not selected.

Optionally, the pressure changes are larger than P region of the _three pressure tappings place as P, and P ₂ pressure tappings spots. A pressure loss generating member may be disposed at the pressure outlet P ₃ to at least partially compensate for the effect of these pressure changes. This is illustrated, for example, by the plug 39 shown in Fig. 3 and placed in the tube 38.

The positioning and design of this plug 39 allows the asymmetry of the output signal S to be eliminated and measurement loss is avoided.

The output of the pressure sensor 40 is led to the input of a signal processing unit 42 which converts the output signal S into rectangular signals. This will be the output signal C of the signal processing unit 42. The conversion is based on a pre-set threshold.

The frequency of the rectangular array will be twice that of the prior art devices mentioned in the introduction. Each rectangular wave corresponds to a volume of liquid flowing through the flow meter, and this value is smaller, usually half the volume that can be measured with known solutions. The rectangular signals are counted by a counter 44 connected to the output of the signal processing unit 42, the output signal D of which is the fluid circulating through the flow meter during the counting.

EN 217 737 Β and is thus proportional to the flow rate.

Since the number of units of volume counted is smaller, it is expedient to be half of the value of known solutions, thus, of course, the measurement accuracy will be higher.

Claims (1)

PATENT CLAIMS A fluid two-dimensional flowmeter with a fluid beam oscillating transversely to the longitudinal plane of symmetry of the flowmeter and having a oscillator chamber (14) on both sides thereof, a barrier (22) disposed in the oscillator chamber (14), a cavity (24) positioned in the flow path and scanned by the beam during oscillation of the jet, and the flow rate by measuring the pressure difference, and the signal processing elements determining the flow rate from the pressure, characterized by a symmetry of the flowmeter (P); between a pressure outlet (P ₃ ) disposed in the intersection of the circumference of the cavity (24) and a pressure outlet (P _b P ₂ ) symmetrically disposed on both sides of this pressure outlet (P ₃ ) and the symmetry plane (P) tti pressure differential element. Fluid oscillator flowmeter according to claim 1, characterized in that the pressure outlet locations (P _b P ₂ ) are located at points corresponding to the maximum deflections of the beam within the cavity (24). 15 third fluid oscillator flowmeter as claimed in claim 1, characterized in that a pressure loss generating element is disposed in the plane of symmetry (P) and the hole (24) of the bottom pressure tappings located at position of the intersection of the plane (P _3).